DE2655527B1 - Projection screen and method for its production - Google Patents

Description

The invention relates to a projection screen of the type mentioned in the preamble of claim Type and a process for its production.

Well-known projection screens can be divided into two groups:

a) Diffusely scattering projection screens with a matt surface, the brightness of the image depending on the viewing angle is largely independent,

b) selectively scattering projection screens that concentrate the light scattered on the screen surface within a certain solid angle, namely in a first subgroup b ₁ in a solid angle including the direction of incidence of the light and in a second subgroup b ₂ in a direction of reflection of the light at the Solid angle enclosing the plane of the projection screen. Known projection screens with a pearl, lens or prism structure belong to the subgroup ö,) and projection screens with a rough metallized structure

Surface of subgroup b ₂ .
The light yield and the radiation characteristics of a projection screen can be shown in a polar diagram, which shows the luminance ίο of the light scattered on the projection screen as a function of the viewing angle under certain lighting conditions. Such a polar diagram is shown in FIG. 1, in which P denotes the projection screen plane / the direction of illumination π and φ denotes the viewing angle. The semicircular curve A shows the radiation characteristics of a diffusely scattering projection screen of group α and the pear-shaped curve B the radiation characteristics of a known, selectively scattering projection screen with high efficiency of group b.

The radiation characteristic is derived from the polar diagram in FIG. 1 in just one level. To get a complete picture of the radiation characteristics 2 ·> To get a projection screen, you need the polar diagram can also be recorded for other planes in the direction of illumination / lying. Isotropes With perpendicular incidence of light, projection screens show the direction of / including the lighting for all Planes have the same polar behavior, anisotropic projection screens, on the other hand, for different ones Different polar behavior.

In the case of an isotropic projection screen, maximum light output is achieved if all of the incident light is only backscattered within a cone - and evenly. In FIG. 2, the course C in the shape of a sector of a circle represents the radiation characteristics of such an ideal projection screen, which backscatters the incident light uniformly within a scattering angle β. A small scattering angle β results in a bright projection image and accordingly limits the space within which the image can be viewed. A radiation characteristic according to the course C could not even come close to being realized so far. In many cases, the viewer of a projection screen occupies a seating arrangement that is horizontally diversified and vertically delimited by a narrow band. The light scattered back above and below this narrow band is wasted. In such cases, anisotropic projection screens, which backscatter the incident light horizontally at a scattering angle β _H and vertically at a narrower scattering angle β _H, achieve a higher degree of efficiency than isotropic projection screens.

The present invention is based on the knowledge that the microstructure of an ideal projection screen should have the following properties:
1 - It should be sufficiently fine that it cannot be resolved at the intended minimum viewing distance from the eye.

2. Compared to the wavelength of the projection light, the microstructure should be sufficiently coarse so that wavelength-dependent diffraction effects are avoided.

3. The microstructure should not be periodic so that no moiré effects can occur.

4. It should be of the above-mentioned reflection type b ₂ , so that illuminating and reflected rays can be sufficiently separated by the projector to avoid shadows cast by spectators or visual obstruction.

5. The angle of inclination of surface elements of the microstructure should be limited in angle in such a way that incident light is backscattered horizontally within a selectable scattering angle β _H and vertically within a selectable scattering angle β _v .

6. The angles of inclination should be distributed so homogeneously that within the range given under 5 Scattering angle the intensity of the reflected light is directionally invariant.

7. Multiple reflections on the microstructure that reduce efficiency are avoided will.

8. The microstructure should not cause any depolarization.

9. The absorption should be as low as possible.

Known projection screens usually meet conditions 1 to 4 quite well, conditions 5. up to 9th, however, in some cases only inadequate. In particular, no projection screen is known that simultaneously all conditions met to a satisfactory degree.

The invention is based on the object of creating a projection screen that meets all requirements 1. to 9. is fair and which can also be produced in a simple manner.

The invention consists in the features identified in the characterizing part of claim 1. A A method for producing such a projection screen is defined in claim 8.

Some exemplary embodiments of the invention are explained in more detail below with reference to the drawing. Show it

Fig. 1 and 2 polar diagrams,

Fig. 3 twin bladders in section,

Figure 4 shows a micro-structure of a projection screen in horizontal section,

5 shows a microstructure of a projection screen in vertical section,

6 shows a microstructure of a projection screen in a perspective illustration and

7 shows a projection screen clamped in a holder.

In Fig. 3 two abutting liquid bubbles 1, 2 of the same size as well as two abutting, differently sized liquid bubbles 3, 4 made of soap solution, liquid plastic and the like are shown. For reasons of static equilibrium, three abutting lamellae of such twin bubbles always form an angle γ = 120 °, regardless of their size.

This angle law is used in the invention, for. B. made of foamed plastic Projection screen used, the structural elements of which according to FIG. 4 have the shape of the surface of having abutting bubbles 5. The outermost boundary surface 6 of the statistically distributed on a plane, bubbles 5 of approximately the same size approximately form a surface that is piece-wise smooth in the mathematical sense. 4 shows a surface element 7 of this surface structure formed by the bubbles 5 indicated, its surface normal relative to a perpendicularly incident light beam 8 by an angle of inclination α is inclined. It is easy to see that the angle of inclination u of such surface elements 7 in the Range -30 ° <α <30 ° with the same frequency, but larger angles of inclination do not occur.

So really only the outermost interface 6 of the

j bubbles 5 are optically effective, this is mirrored. The incident light is then only reflected uniformly within a cone with a scattering angle β of 120 ° (FIG. 2) and, if the bubbles 5 are sufficiently small for an observer, diffusely reflected within this angle. In addition, by limiting the angle of inclination α to ± 30 °, multiple reflections which deteriorate the efficiency are avoided, which also largely prevents depolarization.

The angle of inclination α of the surface elements 7 can be limited to a range that is smaller than ± 30 ° by stretching the bubbles 5 in the plane of the projection screen and thereby increasing the angle γ between the lamellae of the bubbles. This enables both the horizontal scattering angle ß _H and the vertical scattering angle ß _{v to} be set as desired. If the bubbles 5 are stretched predominantly in the vertical axis of the projection screen, an anisotropic radiation characteristic results. FIG. 5 shows the microstructure of such a projection screen with bubbles 5 stretched in the vertical axis, in vertical section, and FIG. 6 in a three-dimensional representation. The horizontal axis of the projection screen is in the

6 with X, the vertical axis with Y, the axis perpendicular to the XY plane with Z, the mean radius of the outer bubble surface in the plane XZ with r, and in the plane YZ with r _z , the length in the axis X denoted by d _x and d ₂ in the Y axis.

Tests have shown that with a film made of foamed plastic, which has been stretched in the vertical axis Y of the projection screen, a vertical scattering angle β _v of only 20 ° can be easily achieved, which is expressed in a correspondingly high efficiency of the projection screen. The horizontal scattering angle β _H can also be narrowed if the bubbles 5 are additionally stretched horizontally.

A narrow vertical scattering angle β _v requires the projection screen to be slightly curved around a horizontal axis in the sense of a cylindrical concave mirror, so that the light incident on the projection screen at different heights is reflected evenly from all points on the screen towards the viewer. A broad horizontal scattering angle β _H makes a corresponding curvature about a vertical axis unnecessary. 7 shows such a curved projection screen 9, which consists of a foamed plastic film 11 drawn onto a rigid, flat carrier 10 and is clamped in a holder 12. The desired radius of curvature of the projection screen 9 can be adjusted with the holder 12. This allows the usable viewing distance range to be varied, the depth of which can be determined by a suitable choice of the vertical scattering angle β _v.

From what has been said above it is easy to see that with the projection screen described all requirements set out above are met and a radiation characteristic according to FIG. 2 is achieved can be. The achieved high efficiency of the projection screen allows compared to conventional Projection screens have a strong reduction

tion of the light output of the projector or, with the same light output, the projection of a bright and high-contrast image in a fully illuminated room, as the light of the room lighting is not reflected as disruptive scattered light in the direction of the audience thanks to the narrow vertical scattering angle ß _{v of the projection screen.}

As already mentioned, a film is suitable as a projection screen with the described microstructure made of foamed plastic, which is optionally stretched in at least one axis. Particularly well suited is a film made of foamed polypropylene. Depending on the stretching process, it can happen that the Bubble surface collapses because of the negative pressure resulting from the increase in volume, so that the convex bubble structure turns into a concave structure. The macroscopically observable In spite of this inversion, the scattering characteristic practically does not change.

To mirror the surface, a thin metal layer z. B. vapor-deposited from aluminum whose high reflectance prevents incident light from being absorbed by the plastic and / or scattered in undesired directions. The metallized surface can be retrospectively with a thin transparent protective layer, e.g. B. with a layer of lacquer against mechanical damage to be protected. The lacquer layer can also serve to influence the radiation characteristics of the projection screen within certain limits. Preferably the plastic film is drawn onto a rigid or rigid flat support in order to provide a for to achieve sufficient rigidity of the projection screen for practical use.

A projection screen with the described microstructure can also be produced by that the surface structure of a foamed plastic on a flat body made of suitable Material, e.g. B. made of plastic, is molded. The surface structure of the foamed plastic by chemical or galvanic coating serving as an embossing die Copy made of metal and die with this embossing die using pressure and heat Micro structure embossed in a flat body made of thermoplastic material. This Process enables cost-saving mass production. The molding of the surface structure of the foamed plastic can of course also serve as a projection screen directly on one-o the plastic with a low softening point or on a curable plastic.

Preferably, it is not the foamed plastic but rather the flat body after molding stretched to the surface structure of the foamed plastic. This allows when stretching Any indefinable deformations that may occur from foamed plastic can be avoided.

The duplicate produced by molding a foamed plastic can in the same way metallized and used as a reflective projection screen, as described above for the foamed one Plastic existing original is described. It is also possible to copy the duplicate from a transparent material and without surface mirroring as a transmission projection screen to use. The radiation characteristics of such a transmission screen differ although somewhat different from those of the reflection screen described, the essential properties, namely the statistical distribution of the structural elements, the frequency distribution of the angles of inclination, a limitation the scattering angle and, if applicable, the anisotropy, are retained.

The above-described measure of the curvature of the reflection projection screen for focusing of the reflected light into the observation area is thereby caused by the transmission projection screen replaces that immediately in front of or behind the transmission projection screen a spherical or cylindrical Converging lens, preferably a Fresnel lens, is arranged.

1 sheet of drawings

Claims (8)

Patent claims: 1. Projection screen whose surface facing the viewer has the radiation characteristics has determining microstructure, which is distributed by a large number of irregularly Structural elements is formed, d a d u r c h g e k e η nze I η et that the micro structure by a surface structure corresponding to abutting bubbles (5) foamed plastic a flat body (11) is formed. 2. Projection screen according to claim 1, characterized in that the microstructure by a butting bubbles (5) foamed and stretched in at least one axis of plastic corresponding surface structure is formed. 3. Projection screen according to claim 1 or 2, characterized in that the flat body (11) is a sheet of foamed plastic. 4. Projection screen according to claim 1 or 2, characterized in that the surface structure the bubbles (5) of the foamed plastic is molded into the flat body (11). 5. Projection screen according to one of claims 1 to 4, characterized in that the flat Body (11) is coated with a reflective layer. 6. Projection screen according to claim 5, characterized in that the reflective layer with a transparent protective layer is coated. 7. Projection screen according to one of claims 1 to 6, characterized in that the flat Body (11) attached to a rigid flat support (10) and in a holder (12) is clamped and has an adjustable cylindrical curvature. 8. A method for producing a projection screen according to claim 4, characterized in that that of the surface structure of the bubbles (5) of the foamed plastic by chemical and / or galvanic coating, a copy serving as an embossing die is produced from metal and with this embossing die the microstructure is created using pressure and heat is embossed in the flat body (11).